Solar panel rack

ABSTRACT

A solar panel rack may comprise one or more sheet metal brackets configured to attach solar panels to the solar panel rack. The sheet metal brackets may include clinching tabs configured to be clinched to features on the solar panels to attach the solar panels to the solar panel rack. The sheet metal brackets may further include protrusions configured to facilitate electrical contact between the brackets and the solar panels when the clinching tabs are clinched to features on the solar panels. The sheet metal brackets may additionally or alternatively include positioning tabs configured to contact features on the solar panels to position the solar panels in desired locations on the solar panel rack.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims benefit of priority to U.S. Provisional Patent Application No. 61/842,516 titled “Solar Panel Rack” and filed Jul. 3, 2013, which is incorporated by reference herein in its entirety.

FIELD OF THE INVENTION

The invention relates generally to the collection of solar energy, and more particularly to solar panel mounting racks and their components.

BACKGROUND

Ground-mounted photovoltaic solar panels are conventionally supported on solar panel mounting racks. Commercially available solar panel racks are typically produced using aluminum extruded sections or steel roll formed sections in order to provide the structural strength required to withstand loads associated with outside conditions such as wind and snow.

SUMMARY

Solar panel racks, their components, and related methods by which the solar panel racks may be manufactured, assembled, and used are disclosed.

In one aspect, a solar panel rack comprises one or more sheet metal brackets and an underlying support structure to which the sheet metal brackets are attached. Each sheet metal bracket comprises one or more upwardly pointing clinching tabs and one or more upwardly pointing protrusions. The clinching tabs are configured to be clinched to features on a solar panel or solar panel assembly to attach the solar panel or solar panel assembly to the solar panel rack in a desired location in a plane defined by the solar panel rack. The protrusions are configured to facilitate electrical contact between the brackets and the solar panel or solar panel assembly when the features on the solar panel or solar panel assembly are clinched by the clinching tabs.

The features on the solar panel or solar panel assembly may be sandwiched between the protrusions and the clinching tabs when the clinching tabs are clinched, for example.

The upwardly pointing protrusions may be configured to pierce an insulating coating on the features on the solar panel or solar panel assembly when the features are clinched by the clinching tabs. Accordingly, the upwardly pointing protrusions may comprise sharp edges, sharp points, or a combination of sharp edges and sharp points. The upwardly pointing protrusions may have a conical volcano shape, for example.

Each sheet metal bracket may comprise one or more upwardly pointing positioning tabs configured to contact features on the solar panel or solar panel assembly to position the solar panel or solar panel assembly in the desired location. The positioning tabs of each sheet metal bracket may be located, for example, in a square or rectangular arrangement in a central portion of a top panel of the sheet metal bracket and extend upward from the top panel. Each sheet metal bracket may be configured to position and attach adjacent corners of, for example, four solar panels or solar panel assemblies to the solar panel rack.

The electrical contact facilitated by the upwardly pointing protrusions may form part of an electrical path from the solar panel or solar panel assemblies through the one or more sheet metal brackets and the underlying support structure to ground.

The underlying support structure may comprise, for example, two or more hollow sheet metal beams arranged side by side and in parallel with each other to define a plane. The beams may be supported in any suitable manner as described herein, for example. Each sheet metal bracket may have an inner cross-sectional shape substantially conforming to the outer cross-sectional shape of a corresponding hollow sheet metal beam to which it is attached.

Each sheet metal bracket may comprise one or more tabs configured to engage corresponding slots or other openings in the underlying support structure to attach the sheet metal bracket to the underlying support structure, and one or more downwardly pointing protrusions configured to flex a portion of the underlying support structure to provide an elastic restoring force securing the tabs in the slots or other openings. If the underlying support structure comprises hollow sheet metal beams to which the sheet metal brackets are attached, the one or more downwardly pointing protrusions on each sheet metal bracket may be configured to flex an upper panel of the hollow sheet metal beam to provide the restoring force securing the tabs in the slots or other openings.

Each sheet metal bracket may be formed by bending a sheet metal blank along bend lines predefined in the sheet metal blank by bend-inducing features.

In another aspect, a solar panel rack comprises one or more sheet metal brackets and an underlying support structure to which the brackets are attached. Each sheet metal bracket comprises one or more upwardly pointing clinching tabs configured to be clinched to features on a solar panel or solar panel assembly to attach the solar panel or solar panel assembly to the solar panel rack in a desired location in a plane defined by the solar panel rack, one or more tabs configured to engage corresponding slots or other openings in the underlying support structure to attach the bracket to the underlying support structure, and one or more downwardly pointing protrusions configured to flex a portion of the underlying support structure to provide an elastic restoring force securing the tabs in the slots or other openings.

The underlying support structure may comprise, for example, two or more hollow sheet metal beams arranged side by side and in parallel with each other to define a plane, with each sheet metal bracket attached to a corresponding one of the hollow sheet metal beams. The beams may be supported in any suitable manner as described herein, for example. The one or more downwardly pointing protrusions on each sheet metal bracket may be configured to flex an upper panel of the hollow sheet metal beam to provide the restoring force securing the tabs in the slots or other openings.

Each sheet metal bracket may comprise one or more upwardly pointing positioning tabs configured to contact features on the solar panel or solar panel assembly to position the solar panel or solar panel assembly in the desired location. The positioning tabs of each sheet metal bracket may be located, for example, in a square or rectangular arrangement in a central portion of a top panel of the sheet metal bracket and extend upward from the top panel. Each sheet metal bracket may be configured to position and attach adjacent corners of, for example, four solar panels or solar panel assemblies to the solar panel rack.

If the underlying support structure comprises hollow sheet metal beams to which the sheet metal brackets are attached, each sheet metal bracket may have an inner cross-sectional shape substantially conforming to the outer cross-sectional shape of the hollow sheet metal beam to which it is attached.

Each sheet metal bracket may be formed by bending a sheet metal blank along bend lines predefined in the sheet metal blank by bend-inducing features.

Solar panel racks, their components, and related manufacturing and assembly methods disclosed herein may advantageously reduce material, manufacturing and installation costs for solar panel systems. This may result from a reduced amount of material used in the solar panel rack design, the use of cost-effective manufacturing methods, reduced shipping costs of solar panel rack components, which may be shipped to an installation site as substantially flat sheet metal blanks prior to bending to form the components, reduced storage space required for the components, and reduced labor requirements for installing the solar racks and/or an increased rate of installation.

These and other embodiments, features and advantages of the present invention will become more apparent to those skilled in the art when taken with reference to the following more detailed description of the invention in conjunction with the accompanying drawings that are first briefly described.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1C show several views of a portion of an example solar panel rack with solar panels mounted on the rack (FIGS. 1A, 1B) and without solar panels mounted on the rack (FIG. 1C).

FIGS. 2A-2B show a transverse support in an example solar panel rack (FIG. 2A) and an expanded view (FIG. 2B) of a notch in the transverse support configured to receive and attach to a beam bracket that is configured to attach a longitudinal beam to the transverse support.

FIGS. 3A-3C show beam brackets attached to and positioned in notches in a transverse support (FIG. 3A), an expanded view of a beam bracket positioned in a notch with its upper flanges open to receive a longitudinal beam (FIG. 3C), and an expanded view of a bracket positioned in a notch with the bracket's upper flanges closed (FIG. 3B).

FIGS. 4A-4C show longitudinal beams positioned in beam brackets attached to a transverse support, with the upper flanges of the beam brackets open (FIG. 4A) and closed (FIG. 4B, 4C) to secure the longitudinal beams to the transverse support.

FIGS. 5A-5D show several views of a beam bracket configured to attach longitudinal beams to transverse support structures in the example solar panel rack.

FIG. 6A shows a sheet metal blank that may be folded to form a hollow longitudinal beam for the example solar panel rack, FIG. 6B shows an expanded view of a portion of the blank of 6A, FIGS. 6C-6H show several views of the longitudinal beam at different stages of folding, FIG. 6I shows an expanded view of a sheet metal blank as in 6A comprising bend-inducing features formed with a lance, and FIG. 6J shows an expanded view of a sheet metal blank as in 6A comprising bend-inducing features formed by laser-cutting.

FIGS. 7A-7G show several views of a collapsible and expandable internal splice and its use in coupling two hollow beam sections together to form a longer hollow beam.

FIGS. 8A and 8B show a longitudinal beam end cap (FIG. 8B) and three such end caps at the ends of longitudinal beams in a portion of a solar panel rack (FIG. 8A).

FIGS. 9A and 9B show perspective and side views, respectively, of a panel bracket configured to attach the corners of four neighboring solar panels to a longitudinal beam in the example solar panel rack, FIG. 9C shows a panel bracket attached to a longitudinal beam, and FIGS. 9D-9G show successive stages of attaching four neighboring solar panels to the example solar panel rack using the panel brackets.

FIGS. 10A-10C illustrate a clinching process by which two neighboring solar panels may be simultaneously secured to the example solar panel rack by the panel bracket of FIGS. 9A-9G.

FIGS. 11A and 11B show perspective and side views, respectively, of another variation of a panel bracket configured to attach the corners of four neighboring solar panels to a longitudinal beam in the example solar rack.

FIGS. 12A and 12B show close up views of the panel bracket of FIGS. 11A and 11B, illustrating two variations of a protrusion that may be formed on a panel bracket to facilitate electrical contact between the panel bracket and a solar panel.

FIGS. 13A and 13B show two perspective views illustrating frame portions of solar panels in place on the panel bracket of FIGS. 11A and 11B with the panel bracket clinching tabs not clinched, FIG. 13C shows a corresponding side view of the solar panels in place on the panel bracket with the clinching tabs not clinched, and FIG. 13D shows the same side view as FIG. 13C but with the panel bracket clinching tabs clinched to secure the solar panel frame portions.

FIG. 14A shows a top perspective view of solar panels in place on the panel bracket of FIGS. 11A and 11B with the panel bracket clinching tabs clinched to secure the solar panel frame portions, FIG. 14B shows a cross-sectional view identified in FIG. 14A and a close-up of that cross-sectional view, and FIG. 14C shows a related close-up view of another cross-section of the same assembly of solar panels on a panel bracket.

DETAILED DESCRIPTION

The following detailed description should be read with reference to the drawings, in which identical reference numbers refer to like elements throughout the different figures. The drawings, which are not necessarily to scale, depict selective embodiments and are not intended to limit the scope of the invention. The detailed description illustrates by way of example, not by way of limitation, the principles of the invention. This description will clearly enable one skilled in the art to make and use the invention, and describes several embodiments, adaptations, variations, alternatives and uses of the invention, including what is presently believed to be the best mode of carrying out the invention.

As used in this specification and the appended claims, the singular forms “a,” “an,” and “the” include plural referents unless the context clearly indicates otherwise. Also, the term “parallel” is intended to mean “parallel or substantially parallel” and to encompass minor deviations from parallel geometries rather than to require that any parallel arrangements described herein be exactly parallel. Similarly, the term “perpendicular” is intended to mean “perpendicular or substantially perpendicular” and to encompass minor deviations from perpendicular geometries rather than to require that any perpendicular arrangements described herein be exactly perpendicular.

This specification discloses solar panel mounting racks, their components, and related methods by which the solar panel racks may be manufactured, assembled, and used. As illustrated in the various figures, the disclosed solar panel racks may be used, for example, in a ground-mounted configuration to support photovoltaic panels in fixed positions to collect and convert solar radiation to electricity. Other configurations and applications for the disclosed solar racks will also be described below.

Various components of the disclosed solar panel racks including, for example, the hollow beams, beam brackets, internal expandable beam splices, and solar panel brackets further described below, may be advantageously used in other structures unrelated to solar panels or to the collection of solar energy. The discussion of these components in relation to their roles in the disclosed solar panel rack is not intended to limit the scope of their potential use.

Referring now to FIGS. 1A-1C, an example solar panel rack 100 comprises a vertical support 105, a transverse support 110 attached to an upper portion of the vertical support, and three hollow beams 115 supported by transverse support 110. Hollow beams 115 are arranged in parallel orientations, with their upper surfaces defining a plane in which solar panels are to be supported. In the illustrated example, hollow beams 115 are secured in notches 117 (FIG. 2A) in transverse support 110 by beam brackets 120. Panel brackets 125, attached to hollow beams 115, are configured to attach solar panels 130 to the upper surfaces of beams 115.

Although the illustrated solar panel rack comprises three parallel hollow beams, more generally the solar panel rack comprises two or more parallel hollow beams arranged to define a plane in which solar panels are to be supported. Transverse support 110 and hollow beams 115 may be configured so that the plane in which the solar panels are supported is tilted with respect to vertical, rather than oriented horizontally. The tilt angle may be selected to allow the solar panels to better collect solar energy. (In this specification, “vertical” indicates the direction opposite to the force of the Earth's gravity). For example, and as illustrated, vertically oriented substantially identical notches 117 in the upper edge of transverse support 110 may be located to secure the beams 115 at progressively varying heights so that the beams can define a plane having a desired tilt angle. Further, beams 115 may have non-rectangular cross-sections (FIG. 6D) such that flat upper surfaces of the hollow beams are angled with respect to the vertical to define the desired tilted plane. The upper edge of transverse support 110 may be angled substantially parallel to the intended plane of the solar panels, as illustrated, to provide clearance for the solar panels.

The portion of the example solar panel rack illustrated in FIGS. 1A-1C may be repeated as a unit to form a linearly extending, modular, solar panel rack of desired length. In such linearly extending solar panel racks, corresponding hollow beams in adjacent repeating units may be arranged collinearly and spliced together with internal expandable splices 135 as further described below. Two or more such linearly extending solar panel racks may be arranged in parallel and side-by-side to support two or more corresponding spaced-apart rows of solar panels in an array of solar panels.

Individual solar panels to be supported by solar panel rack 100 may have, for example, a width of about 0.9 meters to about 1.3 meters and a length of about 1.5 meters to about 2.5 meters. More generally, such solar panels may have any suitable dimensions. The width of the solar panel rack may be selected, for example, to be approximately equal to an integer multiple of the solar panel width or length, or to a sum of integer multiples of the solar panel width and the solar panel length. As illustrated, for example, the solar panel rack may have a width approximately equal to twice the length of a solar panel. More generally, solar panel rack 100 may have any suitable width. Solar panels may be grouped into assemblies of solar panels prior to being installed on solar panel rack 100. Such a solar panel assembly may be handled and installed similarly to as described herein for an individual solar panel.

Beams 115 may have lengths of, for example, about 3 meters to about 8 meters. The beam lengths may be selected, for example, to be approximately equal to an integer multiple of the solar panel width or length, or to a sum of integer multiples of the solar panel width and the solar panel length. Two or more beams 115 may be spliced together as noted above to form part of a solar panel rack having an overall length of, for example, about 24 meters to about 96 meters supported by multiple transverse supports 110 and corresponding vertical supports 105. Though FIGS. 1A-1C show a single transverse support used to support one beam-length of solar panel, in other variations two or more transverse supports 110, with corresponding vertical supports 105, may be spaced along a beam-length of the solar panel. For example, in linearly extending solar panel racks comprising beams collinearly spliced together to lengthen the rack, there may be one, two, or more than two transverse supports spaced along the solar panel rack between beam splices or between the end of the solar panel rack and a beam splice.

Although the example solar panel rack of FIGS. 1A-1C is shown comprising a vertical support, a transverse support, hollow beams, brackets for attaching the hollow beams to the transverse support, and brackets for attaching the solar panels to the hollow beams, variations of the solar panel rack may lack any one of these components, or lack any combination of these components, and may comprise additional components not shown.

Transverse supports, hollow beams, and brackets used in the solar panel racks disclosed in this specification may advantageously be formed by bending sheet metal blanks into the desired shape. Flat sheet metal blanks from which these components are formed may be patterned, for example, with slits, grooves, score lines, obround holes, or similar bend-inducing features that define predetermined bend lines along which the sheet metal blanks may be bent to form the desired structures.

Such bend-inducing features may include, for example, slits, grooves, displacements, and related bend-inducing features as disclosed in U.S. Pat. No. 6,877,349, U.S. Pat. No. 7,152,449, U.S. Pat. No. 7,152,450, U.S. Pat. No. 7,350,390, and US Patent Application Publication No. 2010/0122,563, all of which references are incorporated herein by reference in their entirety. A “displacement” as disclosed in these references is a bend-inducing feature comprising a tongue of material defined in a sheet metal blank by a cut or sheared edge located on or adjacent the bend line, with the tongue displaced at least partially out of the plane of the sheet metal blank before the sheet metal blank is bent along that bend line. The use of bend-inducing features, particularly those disclosed in these references, may increase the precision with which the sheet metal blanks may be bent into the desired components and reduce the force necessary to bend the blanks. The bend-inducing features disclosed in the cited references may exhibit edge-to-face engagement, as described in the references, upon bending. Such edge-to-face engagement may contribute to the precision with which bending may be accomplished and to the stiffness and strength of the resulting component.

Example flat sheet metal blanks from which hollow beams 115 may be formed in some variations are illustrated in FIGS. 6A-6J and described below. For other components of solar panel rack 100 for which no corresponding flat sheet metal blank with bend-inducing features is illustrated, the predetermined bend lines defined by bend inducing features in such sheet metal blanks should be understood to be located at positions corresponding to the bends evident in the finished structures shown in the drawings.

In some variations, transverse supports, hollow beams, and/or brackets used in the solar panel may be formed from sheet metal blanks without the use of bend-inducing features to predefine the bend lines. In such variations, the sheet metal blanks may be bent into the desired shape using, for example, conventional press-brake, stamping press, or roll-forming technology.

Sheet metal blanks for the components of solar panel rack 100, including bend-inducing features if used, may be formed using laser cutting, computer numerical controlled (CNC) metal punching, and/or metal stamping, for example. Such techniques allow for low cost manufacturing of the components.

The use of sheet metal components in solar panel rack 100 allows such components to be attached to each other using sheet metal screws or other sheet metal fasteners, rather than with double sided bolt/washer/nut fastener assemblies which can be difficult and slow to install. The single sided installation process of driving a sheet metal screw using, for example, a magnetic electric drive attachment may be advantageous for both the reduced cost of the fasteners and the increased ease and speed of installation. The use of sheet metal components as described herein may also reduce the overall amount and weight of material used in the solar panel racks while maintaining desired stiffness and strength. Nevertheless, as suitable, one or more components not formed from bent sheet metal, such as cast, extruded, or machined components, for example, may be substituted for the sheet metal components otherwise described in this specification.

The individual components of the example solar panel rack 100 of FIGS. 1A-1C are next described in further detail with respect to additional drawings.

Referring again to FIGS. 1A-1C, vertical support 105 may be, for example, any conventional pile or post suitable for supporting solar panel rack 100 and may be formed from any suitable material. Vertical support 105 may have a Σ (sigma) cross section, for example. Although FIGS. 1A-1C show only one vertical support 105 attached to transverse support 110, other variations of the solar panel rack may use two or more such vertical supports spaced apart and attached to transverse support 110. For ground-mounted configurations, vertical support 105 may be, for example, driven into the ground, ballasted with respect to the ground, screwed into the ground, or affixed to or upon the ground by any other suitable means.

As illustrated in the various figures, transverse support 110 has a saddle shape selected to reduce the amount of material necessary to provide sufficient strength and stiffness to support beams 115 and solar panels 130. As noted above, notches 117 in the upper edge of transverse support 110 are configured to receive brackets 120 and beams 115. Any other suitable shape or configuration for transverse support 110 may also be used.

Transverse support 110 may be attached to vertical support 105 using bolt/washer/nut assemblies or any other suitable fasteners or method. Attachment may be accomplished, for example, with suitable fasteners passing through vertical slots in vertical support 105 and through horizontal slots in transverse support 110. Alternatively, attachment may be accomplished, for example, with suitable fasteners passing through horizontal slots in vertical support 105 and through vertical slots in transverse support 110. Such arrangements of vertical and horizontal slots provide an adjustment that may be used to compensate for imprecision in the placement of vertical support 105 with respect to other vertical supports in the solar panel rack.

Referring now to FIGS. 2A and 2B, in the illustrated example transverse support 110 is formed from a flat sheet metal blank that is bent along predefined bend lines to form panel section 110 a, upper flange 110 b, and lower flanges 110 c. Upper flange 110 b and lower flanges 110 c are bent perpendicular to panel 110 a to impart stiffness to panel 110 a. The sheet metal blank for transverse support 110 is also bent along predefined bend lines to form flanges 110 d, which are oriented perpendicular to panel 110 a to form side walls to notches 117. Panel 110 a includes one or more tabs 140 projecting into each notch 117. Variations including two or more tabs per notch, for example, may have one or more tabs projecting into the notch from either side of the notch. In variations having only one projecting tab per notch, the tabs on the outer notches may preferably be located on the sides of the notches interior to the solar panel rack, away from the edges of the solar panel rack. Tabs 140 may be defined in the sheet metal blank by sheared or cut edges, and remain in the plane of panel 110 a, or at least substantially parallel to the plane of panel 110 a, when flanges 110 d are bent perpendicular to panel 110 a. As described below, tabs 140 may be inserted into slots or other openings in brackets 120 to temporarily secure brackets 120 in notches 117 without the use of fasteners. Although two tabs 140 are used for each notch 117 in the illustrated example, any other suitable number of tabs 140 may be used per notch. Alternatively, flanges 110 d may comprise one or more preformed slots or other openings into which one or more tabs on brackets 120 may be inserted to temporarily secure brackets 120 in notches 117. In the illustrated example, the dimensions and cross-sectional shape of notches 117 in transverse support 110 are selected to conform to the shape of brackets 120 and to provide a friction fit for brackets 120.

The predefined bend lines in the sheet metal blank for transverse support 110 may comprise any suitable bend-inducing features as described herein, known in the art, or later developed. The sheet metal blank for transverse support 110 may be formed, for example, from galvanized steel sheet having a thickness, for example, of about 1.9 millimeters. Any other suitable material and thickness may also be used.

Referring now to FIGS. 3A-3C, 4A-4C, 5A, and 5B, in the illustrated example bracket 120 is formed from a flat sheet metal blank that is bent along predefined bend lines to form bottom panel 120 a, side panels 120 b, and upper flanges 120 c. Side panels 120 b are bent with respect to bottom panel 120 a to form a bracket shape conforming to the shape of notch 117 (Figure B) and to the cross-sectional shape of beams 115 (FIG. 6D). Upper flanges 120 c may be bent to close (FIG. 3B) and to open (FIG. 3C) the upper end of bracket 120. Side panels 120 b comprise slots 120 d configured and positioned to engage with corresponding tabs 140 on flanges 110 d of transverse support 110 when brackets 120 are properly positioned in notches 117 in transverse support 110.

The predefined bend lines in the sheet metal blank for bracket 120 may comprise any suitable bend-inducing features as described herein, known in the art, or later developed. The sheet metal blank for bracket 120 may be formed, for example, from galvanized steel sheet having a thickness, for example, of about 1.9 millimeters. Any other suitable material and thickness may also be used.

Once bent into shape, brackets 120 are inserted into notches 117 and temporarily secured in place by engaging tabs 140 on transverse support 110 with slots 120 d on brackets 120. Beams 115 are positioned in place in brackets 120 (FIG. 4A), and then upper flanges 120 c of brackets 120 are bent into their closed positions (FIGS. 4B, 4C) to capture beams 115 within brackets 120. Sheet metal fasteners may then be driven through preformed holes 110 e in flanges 110 d of transverse support 110 and through correspondingly aligned preformed holes 120 e in bracket 120 into beams 115 to secure the brackets 120 and the beams 115 to transverse support 110. Additional sheet metal fasteners may be driven through preformed holes 120 f in upper flanges 120 c of brackets 120 into beams 115 to further secure beams 115 to brackets 120. The sheet metal fasteners attaching transverse support 110 and brackets 120 to beams 115 may preferably be self-drilling fasteners that drill into and engage beams 115. The use of such self-drilling fasteners allows the position of transverse supports 110 and vertical supports 105 along beams 115 to be selected at the installation site to adapt to local circumstances, such as to rocks or other objects that might interfere with or constrain the positioning of vertical supports 105. Alternatively, the sheet metal fasteners attaching transverse support 110 and brackets 120 to beams 115 may engage preformed holes in beams 115. (Preformed holes referred to here and elsewhere in the specification are formed in corresponding sheet metal blanks prior to bending of the sheet metal blanks to form the desired components).

The ability to temporarily position brackets 120 in transverse support 110 without the use of fasteners, by means of the tab and slot arrangement just described, allows beams 115 to be positioned in the solar panel rack prior to final attachment of the brackets using sheet metal screws. A benefit of this arrangement is that installers need not handle multiple components at one time, nor are fasteners handled at that same time as well. De-coupling complex installation steps may facilitate faster installation as well as lower the labor costs and skill required.

The inventors have recognized that hollow sheet metal beams such as beams 115 may buckle under load if they are supported by hard narrow edges that concentrate the reaction force from the supporting structure onto a narrow region of the hollow beam. Brackets 120 increase the load capacity of beams 115 by distributing the force from the load on beams 115 along the length of the brackets. This helps to prevent buckling that might otherwise occur if the force from the load on beams 115 were concentrated at the hard upper edge of transverse support 110. Further, each bracket 120 may be shaped so that its stiffness progressively and gradually decreases with distance in both directions away from transverse support 110 along its beam 115. (The stiffest portion of a bracket 120 is the central region of the bracket that is in contact with and supported by transverse support 110). Because of this progressive decrease in stiffness, the ends of brackets 120 away from transverse support 110 displace significantly downward under load and consequently do not themselves present hard edges that promote buckling of beams 115.

Referring now to FIGS. 5A-5D, in the illustrated example brackets 120 have stiffness that progressively decreases with distance from transverse support 110 because bottom panels 120 a, side panels 120 b, and upper flanges 120 c all have widths that progressively decrease from a wide central portion to narrower portions at the panel's outer edges, farthest from transverse support 110. That is, material has been removed from central regions of the panels away from the transverse support 110, with the regions from which material has been removed having widths that increase with distance from transverse support 110. This configuration enhances load capacity in all four primary load directions—vertically upward, downward, and in both lateral directions. Any other suitable shape or configuration of brackets 120 may also be used to provide the progressive decrease in stiffness just described. For example, the progressive decrease in stiffness of the bracket may alternatively be provided by progressive changes in width of only some of its panels, although such a configuration may not enhance load capacity in directions perpendicular to the panels that do not exhibit progressively reduced stiffness. Further, although the illustrated brackets 120 are symmetric about transverse support 110 and about hollow beams 115, neither of these symmetries is required.

The use of brackets 120 exhibiting progressive decreases in stiffness as described in this specification may advantageously increase the capacity of a solar panel rack to handle high loads caused by wind or snow, for example. Brackets 120 are not required to exhibit such progressive decreases in stiffness, however. For example, the bottom panels, side panels, and upper flanges of bracket 120 may be formed as complete panels without material removed from central regions as described above, and thus fully wrap the bottom and side panels of a beam 115 for the length of the bracket 120. In such variations, the bracket 120 may have a length of, for example, about 1/10 of the beam length to about ⅓ of the beam length. Brackets of sufficient length, for example greater than or equal to about ⅓ of the beam length, may advantageously spread the load on the beam along the beam to significantly reduce a stress spike that may otherwise occur in the beam. Also in such variations, the bracket 120 may have a length of, for example, about 2 times the beam height (or about 2 times the largest cross-sectional dimension perpendicular to the beam length) to about 7 times the beam height (or about 7 times the largest cross-sectional dimension perpendicular to the beam length). Brackets of sufficient length, for example greater than or equal to about 5 times the beam height (or about 5 times the largest cross-sectional dimension perpendicular to the beam length), may advantageously spread the load on the beam along the beam to significantly reduce a stress spike that may otherwise occur in the beam. In such variations (in which the bottom panels, side panels, and upper flanges of bracket 120 may be formed as complete panels without material removed from central regions), bracket 120 may be formed, for example, from galvanized steel sheet having a thickness of, for example, about 1.5 millimeters. Any other suitable material and thickness may also be used.

Referring now to FIGS. 6A-6J, in the illustrated example each beam 115 is formed from a flat sheet metal blank 145 (FIGS. 6A-6C, 6I, 6J) that is bent along predefined bend lines to form a beam 115 having a quadrilateral cross-section comprising bottom panel 150 a, side panel 150 b, top panel 150 c, side panel 150 d, and closure flanges 150 e and 150 f (FIGS. 6D-6H). Upon bending of sheet metal blank 145 into the desired cross-sectional shape, flange 150 e and bottom panel 150 a overlap, and flange 150 f and side panel 150 d overlap. Flanges 150 e and 150 f may then be fastened to the panels with which they overlap using sheet metal fasteners passing through preformed holes, for example, or by any other suitable method, to secure beam 115 in its closed configuration.

In the illustrated example, beam 115 is secured in its closed configuration using tabs and slots preformed in sheet metal blank 145. As illustrated, flange 150 f comprises a repeating pattern of tabs 155 and flange 150 e comprises a corresponding repeating pattern of slots 160 formed along the bend line between flange 150 e and side panel 150 d. When sheet metal blank 145 is bent to form the desired cross-sectional shape, tabs 155 remain in the plane of bottom panel 150 a, or at least substantially parallel to the plane of bottom panel 150 a, and thus protrude from flange 150 f. These protruding tabs 155 may be inserted through corresponding slots 160 (FIGS. 6E, 6G) and then bent to lie flat alongside panel 150 d (FIGS. 6F, 6H) to secure bottom panel 150 a to side panel 150 d.

Preformed tabs 155 may be formed as tongues of material defined by a cut or sheared edge, with the tongues displaced at least partially out of, but still substantially parallel to, the plane of sheet metal blank 145 prior to bending (FIGS. 6B, 6C, 6I). This may be accomplished using sheet metal lancing methods, for example. Alternatively, preformed tabs 155 may be formed as tongues of material defined by a laser-cut edge, with the tongues remaining within the plane of sheet metal blank 145 prior to bending of the blank (FIG. 6J).

The use of integrated tabs 155 and slots 160 as just described allows sheet metal blank 145 to be bent into shape and joined to itself to form a beam 115 without the use of welding, fasteners, or other means of joinery. Such other means of joinery may be used in addition to such tabs and slots if desired, however.

As noted above, beams 115 as illustrated have quadrilateral cross-sectional shapes. Such quadrilateral cross-sectional shapes may allow beams 115 to provide optimal load capacity in all four primary load directions—vertically upward, downward, and in both lateral directions. (Lateral loads may be caused by wind, for example). Other cross-sectional beam shapes may also be used, however, if suitable.

Sheet metal blank 145 may comprise preformed holes or slots into which tabs on panel brackets 125 are to be inserted, as further described below. Alternatively, sheet metal blank 145 may comprise predefined features that, upon folding of the blank, form tabs on beam 115 that may be inserted into preformed holes or slots on panel brackets 125. Such tab and slot arrangements predefine the locations of panel brackets 125, and thus of solar panels 130, with respect to the beams in solar panel rack 100. This promotes installation speed and prevents errors that might otherwise occur in positioning panel brackets 125 and solar panels 130 on solar panel rack 100.

The predefined bend lines in sheet metal blank 145 may comprise any suitable bend-inducing features as described herein, known in the art, or later developed. Sheet metal blank 145 may be formed, for example, from galvanized steel sheet having a thickness, for example, of about 0.9 millimeters or about 1.2 millimeters. Any other suitable material and thickness may also be used.

The inventors have determined that the resistance of beams 115 to buckling under stress may be promoted by particular configurations of bend-inducing features used to define the bend lines in sheet metal blank 145. The inventors have recognized that a beam's resistance to buckling increases as the length of the individual bend-inducing features defining the bend lines is shortened. As further explained below, the inventors have also recognized that there is typically a practical lower limit to the length of a bend-inducing feature, with that lower limit related to the composition and the thickness of the sheet of material. These opposing trends result in optimal ranges for the lengths of bend-inducing features used to define bend lines in sheet metal blanks to be formed into hollow beams such as beams 115.

Referring now to FIG. 6I, bend lines in sheet metal blank 145 may be defined by rows of spaced-apart displacements 165, each of which has a length along the bend line identified as “A” in the drawing. Each displacement 165 comprises a cut or sheared edge 165 a of a tongue of material 165 b. Severed edge 165 a is at least partially curved, and typically has ends that diverge away from the bend line. Tongue 165 b is displaced at least partially out of the plane of sheet metal blank 145 at the time displacement 165 is formed, prior to bending of the blank, but remains attached to and substantially parallel to the blank. Lateral ends of the severed edge 165 a, and thus of tongue 165 b, have a radius of curvature R (not shown).

If the radius of curvature R of the ends of the displacements is too small, the sheet metal blank may crack at the ends of the displacements upon folding of the blank. The inventors have determined that the radius of curvature R of the ends of the displacement 165 in sheet metal blank 145 should be selected to be R_(min), or larger than but approximately R_(min), where R_(min) is the minimum radius of curvature that may be used without initiating cracking at the ends of the displacements upon folding the sheet metal blank to form the beam. The practical lower limit to the length of a displacement 165 is approximately 2R_(min). Typically, larger sheet thicknesses require a larger radius of curvature R to prevent cracking More brittle materials also require a larger radius of curvature. The inventors have also found that resistance to beam buckling decreases with increasing displacement length “A”, and that resistance to beam buckling has typically decreased significantly for displacements having a length “A” greater than approximately 6R_(min). Thus inventors have determined that bend inducing displacements to be used in forming a hollow sheet metal beam 115 preferably have a length “A” that satisfies the relationship A≦˜6R_(min), or more preferably satisfies the relationship ˜2R_(min)≦A≦˜6R_(min).

Referring now to FIG. 6J, bend lines in sheet metal blank 145 may alternatively be defined by rows of spaced-apart “smile shaped” slits 170, with adjacent slits on alternating sides of the bend line. Slits 170, which penetrate through sheet metal blank 145, define tongues 170 a that remain in the plane of sheet metal blank 145 prior to bending. As illustrated, lateral ends of the slits 170 diverge away from the bend line. Each of slits 170 has a length along the bend line identified as “A” in the drawing. The inventors have determined that such bend-inducing smile-shaped slits to be used in forming a hollow sheet metal beam 115 preferably have a length “A” that falls within the same range as that for the use of displacements as discussed above. That is, the length A of the smile shaped slits should satisfies the relationship A≦˜6R_(min), or more preferably satisfies the relationship ˜2R_(min)≦A≦˜6R_(min), where R_(min) is the minimum radius of curvature that may be used for displacements (as discussed above) without initiating cracking at the ends of the displacements upon folding the sheet metal blank to form the beam.

Beams 115 may be formed, for example, from galvanized steel sheets having a thickness of about 0.9 millimeters or about 1.2 millimeters and bend lines defined by displacements or smile-shaped slits, as described above, having lengths of about 9 millimeters or less.

As noted above, two beams 115 may be arranged collinearly in a solar panel rack 100 and spliced together using internal splices 135. Referring now to FIGS. 7A-7G, in the illustrated example a splice 135 may be formed from a sheet metal blank that is bent along predefined bend lines to form a short hollow beam section having a quadrilateral cross-section comprising bottom panel 175 a, side panel 175 b, top panel 175 c, side panel 175 d, and closure flange 175 e. Panels 175 a, 175 b, 175 c, and 175 d correspond in position, shape, and orientation to panels in beam 115. Closure flange 175 e may be bent into contact with and optionally fastened to side wall 175 b. Outer cross-sectional dimensions of splice 135 approximately match the internal cross-sectional dimensions of beams 115, to allow a tight fit between the splice and a beam as further described below. Splices 135 may have a length, for example, of about 0.25 meters to about 1.0 meters.

Splice 135, and the sheet metal blank from which it is formed, also comprise two or more additional predefined bend lines which may be bent with low force to partially collapse splice 135. In the illustrated example, splice 135 comprises predefined low-force bend lines 180 and 185 running parallel to the long axis of the splice in side panels 175 b and 175 d, respectively, which are positioned on opposite sides of splice 135. These low force bend lines allow splice 135 to be partially collapsed (FIG. 7C), and then inserted into an end of a hollow beam 115 (FIGS. 7D and 7E). Typically, splice 135 is inserted into beam 115 to a depth of about one half the length of splice 135, as shown in FIG. 7A, for example. A second hollow beam 115 may then be slid over the remaining exposed half length of splice 135.

Splice 135, in its collapsed configuration, may thus be positioned entirely within two adjacent and collinear hollow beams 115. Sheet metal fasteners may then be inserted through preformed clearance holes 190 (FIG. 7E) in each of the two hollow beams 115 to engage preformed holes in side panels 175 b and 175 d of splice 135 to pull splice 135 into its expanded configuration (FIGS. 7F, 7G). The two hollow beams 115 are thereby coupled to each other through their attachment to splice 135. (Note that in order to show a perspective view of an expanded splice 135 in position inside a hollow beam 115, FIG. 7G shows only one of the two hollow beams 115 typically coupled to such a splice).

Further, because the outer cross-sectional dimensions of splice 135 approximately match the internal cross-sectional dimensions of beams 115, when splice 135 is expanded within beams 115 the splice's top, bottom, and side panels fit tightly against the corresponding panels of the beams 115. This provides strength and stiffness that allows splice 135 and its attached beams 115 to handle multidirectional loads. In addition, splice 135 does not interfere with the positions of other components of solar rack 100 that are attached to beams 115, such as panel brackets 125 for example, because splice 135 in its final configuration is located within beams 115.

Hollow beams 115 may optionally comprise preformed holes 195 (FIG. 7E) through which a screwdriver or other object may be temporarily inserted as a stop to control the depth to which a splice 135 is inserted into a hollow beam 115.

The predefined bend lines in the sheet metal blank for splice 135 may comprise any suitable bend-inducing features as described herein, known in the art, or later developed. The sheet metal blank for splice 135 may be formed, for example, from galvanized steel sheet having a thickness, for example, of about 0.9 millimeters to about 1.2 millimeters. Any other suitable material and thickness may also be used.

Referring now to FIGS. 8A and 8B, solar panel rack 100 may also comprise end caps 200 inserted into and closing the ends of hollow beams 115 at the ends of solar panel rack 100. An end cap 200 may be formed from a sheet metal blank bent along predefined bend lines to form end panel 205 a and side flanges 205 b. End panel 205 a may be inserted into the end of a hollow beam 115, with tabs 205 c on end panel 205 a engaging corresponding preformed slots in the hollow beam 115 to retain the end cap in the hollow beam. Alternatively, hollow beam 115 may comprise tabs that are inserted into preformed slots in side flanges 205 b to retain the end cap in the hollow beam. In either case, side flanges 205 b may extend outward from and collinearly with hollow beam 115 to support an overhanging portion of a panel bracket 125 positioned at the end of hollow beam 115 (FIG. 8A).

The predefined bend lines in the sheet metal blank for end cap 200 may comprise any suitable bend-inducing features as described herein, known in the art, or later developed. The sheet metal blank for end cap 200 may be formed, for example, from galvanized steel sheet having a thickness, for example, of about 0.5 millimeters to about 1.2 millimeters. Any other suitable material and thickness may also be used.

Referring now to FIGS. 9A-9G, in the illustrated example a panel bracket 125 is formed from a sheet metal blank that is bent along predefined bend lines to form a top panel 210 a, side panels 210 b bent downward from top panel 210 a so that top panel 210 a and side panels 210 b together conform to the cross-sectional shape of a hollow beam 115, four positioning tabs 210 c located in a square or rectangular arrangement in a central portion of top panel 210 a and extending upward from panel 210 a, four solar panel clinching tabs 210 d extending upward from panel 210 a and each positioned adjacent to a positioning tab 210 c, and flanges 210 e bent perpendicularly outward from side panels 210 b to stiffen side panels 210 b.

Side panels 210 b of panel brackets 125 comprise tabs 210 f that may be inserted into preformed slots in a hollow beam 115 to position the panel brackets at desired locations on the hollow beam (FIGS. 9B, 9C). As further described below, panel brackets 125 are configured to properly position and attach the corners of up to four solar panels 130 to a hollow beam 115. This arrangement allows the preformed slots in hollow beams 115 to predefine the positions of solar panels 130 on solar panel rack 100.

To position and attach solar panels 130 to solar panel rack 100, panel brackets 125 are first positioned on hollow beams 115 using the tab and slot arrangement described above. Panel brackets 125 may then be further secured to the beams with sheet metal fasteners driven through preformed holes 215 in side panels 210 b into preformed holes in hollow beams 115. Solar panels 130 are then guided into position by contact between outer edges of solar panels 130 and positioning tabs 210 c, as well as by contact between solar panels 130 and clinching tabs 210 d (FIGS. 9D-9G).

Clinching tabs 210 d are configured to be clinched around industry-standard features 220 on solar panels 130 to attach the solar panels to panel brackets 125 and thus to hollow beams 115 (FIGS. 10A, 10C). In the illustrated example, a pair of clinching tabs 210 d located on the same side of a hollow beam 115 may be simultaneously clinched around features 220 on adjacent solar panels 130 using a conventional clinching tool shown in FIG. 10B in its open 225A and clinched 225B configurations. This simultaneous clinching method increases the speed of installation. Optionally, solar panels 130 may be further secured to panel brackets 125 with fasteners passing through preformed holes in panel bracket 125. Features 220 may be flanges on an outer frame of solar panel 130, for example.

FIGS. 11A-14C show another variation of panel bracket 125. This variation of the panel bracket is also configured to properly position and attach the corners of up to four solar panels 130 to a hollow beam 115, with slots in hollow beams 115 predefining the positions of solar panels 130 on solar panel rack 100. Referring now to FIGS. 11A and 11B, the illustrated panel bracket 125 is formed from a sheet that is bent along predefined bend lines to form a top panel 230 a, end panels 230 b bent downward from top panel 230 a, side panels 230 c also bent downward from top panel 230 a, top beam attachment panels 230 d bent outward from side panels 230 c into an orientation parallel to top panel 230 a, and side beam attachment panels 230 e bent downward from top beam panels 230 d so that a top beam panel 230 d and its side beam panels 230 e together conform to the cross-sectional shape of a hollow beam 115. End panels 230 b may be bent into position prior to side panels 230 c, provide a hard stop defining the final orientation of side panels 230 c, and brace side panels 230 c in their final position. Side beam attachment panels 230 e comprises (e.g., hook-like) tabs 230 h that may be inserted into preformed slots in a hollow beam 115 to position the panel brackets at desired locations on the hollow beam.

The sheet from which panel bracket 125 is formed is also bent along predefined bend lines to form six positioning tabs 230 f located in a square or rectangular arrangement in a central portion of top panel 230 a and extending upward from panel 230 a, and four solar panel clinching tabs 230 g also extending upward from panel 230 a. As further explained below, these positioning and clinching tabs function similarly to positioning tabs 210 c and clinching tabs 210 d of the panel bracket of FIGS. 9A-9G.

In addition to the features just described, panel brackets 125 of FIGS. 11A-14C include upward pointing protrusions 235, which are configured to facilitate electrical contact between the panel bracket and a metal frame or other conducting feature of a solar panel attached to the solar panel rack by the panel bracket. The electrical contact facilitated by protrusions 235 may form part of an electrical path from the solar panel, through the solar panel rack, to electrical ground. Such a ground path may run, for example, from a metal frame of the solar panel through panel bracket 125 to a beam 115, and then from the beam 115 through a beam bracket 120 to saddle 110, and then from saddle 110 through vertical support 105 to ground.

The metal frame or other conducting component of the solar panels intended to form part of such a ground path may have an insulating or partially insulating coating that reduces its conductivity. For example, anodized aluminum solar panel frames and galvanized steel solar panel frames will likely have such insulating or partially insulating coatings. Protrusions 235 may be configured to pierce such a coating to increase the conductivity of the contact between the panel bracket 125 and the solar panel. This may be accomplished, for example, with a protrusion geometry that provides strength under compression in combination with one or more sharp edges positioned to pierce the insulating coating when clinching tabs 230 g are clinched around the solar panel frame and squeeze the panel frame between protrusions 235 and clinching tabs 230 g.

Any suitable geometry for protrusions 235 may be used. Referring to FIGS. 11A and 12A, protrusions 235 may have, for example, the shape of a conical volcano with a sharp and substantially continuous rim 235 a. In an alternative example shown in FIG. 12B, protrusions 235 have the shape of a conical volcano with a ruptured rim exhibiting sharp points 235 b.

Protrusions 235 may be formed integrally with panel bracket 125. For example, the protrusions illustrated in FIGS. 12A and 12B may be formed in the panel bracket sheet metal blank with a punch and a die. Alternatively, protrusions 235 may be formed separately from panel bracket 125 and then attached to panel bracket 125 by any suitable method.

Referring now to FIGS. 13A-13C, to attach one or more solar panels 130 to a solar panel rack 100 using panel brackets 125 of FIGS. 11A and 11B, the panel brackets 125 are first positioned on hollow beams 115 using the tab and slot arrangement described above. Panel brackets 125 may then be further secured to the beams with sheet metal fasteners driven through preformed holes 237 in side beam attachment panels 230 e. One, two, three, or four solar panels 130 are then guided into position by contact between outer edges of solar panels 130 (e.g., solar panel frames) and positioning tabs 230 f, as well as by contact between solar panels 130 and clinching tabs 230 g.

Referring now to FIGS. 13D-14C, clinching tabs 230 g are configured to be clinched around industry-standard features (e.g., frames) on solar panels 130 to attach the solar panels to panel brackets 125 and thus to hollow beams 115. In the illustrated example, a pair of clinching tabs 230 g located on the same side of a hollow beam 115 may be simultaneously clinched around features on adjacent solar panels 130 using a conventional clinching tool (e.g., as shown in FIG. 10B in its open 225A and clinched 225B configurations). Optionally, solar panels 130 may be further secured to panel brackets 125 with fasteners passing through preformed holes in panel bracket 125.

The close-up cross-sectional view in FIG. 14B, taken along line A-A of FIG. 14A, shows a flange on the frame of a solar panel 130 sandwiched between a protrusion 235 and a clinching tab 230 g, thus facilitating electrical contact between the panel bracket 125 and the solar panel 130 through protrusion 235 as described above. FIG. 14C shows a related cross-sectional view, taken parallel to line A-A of FIG. 14A but further along the panel bracket and away from protrusions 235. As the latter figure shows, away from protrusions 235 the flange of the solar panel frame is bent downward past protrusions 235 to make direct contact with panel bracket top panel 230 a and be sandwiched between top panel 230 a and clinching tab 230 g. Bent in this manner, the flange on the solar panel frame typically exhibits a restoring force toward its original flat configuration that tends to pull the flange tightly against protrusion 235, further enhancing electrical contact between the solar panel and the panel bracket.

Referring again to FIGS. 11A and 11B, in these examples the beam attachment top panels 230 d include downward pointing protrusions 240. These protrusions are configured to elastically flex a top panel of the hollow beam to which the panel bracket is attached, so that the beam exerts a restoring force tending to pull tabs 230 h on beam attachment side panels 230 e toward the top of the beam, thereby tightly securing the tabs in position in the slots that they engage in the beam. In the illustrated examples, protrusions 240 are downward pointing dimples integrally formed in the sheet metal blank for panel bracket 125. Any other suitable geometry for protrusions 240 may be used. Rather than integral with panel bracket 125, protrusions 240 may be separately formed and then attached to beam attachment top panels 230 d.

In variations including protrusions 240, a tight fit between beam attachment panels 230 d and 230 e and the beam and/or contact between tabs 230 h and the beam may provide acceptable electrical contact between the panel bracket and the beam for a desired ground path. Alternatively, or in addition, suitable electrical contact may be provided by fasteners engaging the beam through preformed holes 237 in panels 230 e, or in any other suitable manner.

Protrusions 235 and protrusions 240 may be advantageous but are not required. Further, protrusions 235 may be used without protrusions 240, and protrusions 240 may be used without protrusions 235. Either or both protrusions 235 and protrusions 240 may be used in variations of the panel brackets illustrated in FIGS. 9A-9G, on panel 210 a for example.

In addition to positioning solar panels 130 and attaching them to beams 115, panel brackets 125 as described herein also better distribute the load from solar panels 130 along beams 115 than would be the case if the solar panels were attached directly to beams 115. The ability of a single panel bracket 125 to position and attach corners of up to four solar panels to solar panel rack 100 may reduce part counts and labor, and thus cost.

Although panel brackets 125 are shown has having particular numbers of positioning and clinching tabs, any suitable number of such tabs may be used.

The predefined bend lines in the sheet metal blank for panel bracket 125 may comprise any suitable bend-inducing features as described herein, known in the art, or later developed. The sheet metal blank for panel bracket 125 may be formed, for example, from galvanized steel sheet having a thickness, for example, of about 1.5 millimeters. Any other suitable material and thickness may also be used. Bend lines between top panel 210 a and side panels 210 b may preferably be predefined, for example, by bend-inducing features disclosed in US Patent Application Publication No. 2010/0122,563.

Although the illustrated examples of solar panel rack 100 are described above as configured for ground mounting, solar panel rack 100 may alternatively be mounted on roof-tops. Variations of solar panel rack 100 to be roof-top mounted may use vertical supports 105 as described above, or substitute any suitable vertical support. Any suitable method of attaching solar panel rack 100 to a roof-top may be used.

As illustrated, transverse support 110 in solar panel rack 100 is statically mounted to vertical supports 105 so that solar panel rack 100 maintains a fixed orientation. In other variations, transverse support 110 may be pivotably mounted to vertical supports 105, by any suitable pivot mechanism, to rotate around an axis extending parallel to the long axes of hollow beams 115. This arrangement allows transverse support 110 and beams 115 to be rotated so that solar panels 130 track motion of the sun across the sky during, for example, the course of a day or the course of a year. Any suitable rotation drive may be used to rotate the upper portion of such a solar panel rack 100 in this manner.

Although solar panel rack 100 is described above as supporting photovoltaic solar panels, in other variations the solar panel racks described herein may be used to support solar water heating panels rather than, or in addition to, photovoltaic solar panels. Any suitable modification may be made to the solar panel racks described herein to accommodate mounting such solar water heating panels.

Further, although the rack structures disclosed herein have been described as supporting solar panels, they may instead be used to support reflectors such as mirrors, for example, used to direct solar radiation to a solar energy receiver, for example. Such rack structures supporting reflectors may be statically mounted, or pivotably mounted as described above so that the reflectors may be rotated about an axis to track motion of the sun.

The hollow beams, beam brackets, and hollow beam splices described above are not restricted to use in solar panel racks but may instead be used individually or in any combination with each other in any structure for which they are suitable. Further, the cross-sectional shapes of hollow beams, beam brackets, and splices as disclosed herein are not restricted to the particular quadrilateral cross-sectional shapes shown in the drawings, but instead may take any shape suitable for the purpose for which the beams, beam brackets, or splices are employed. The hollow beam splices described herein are not restricted to use in coupling hollow beams formed from folded sheet metal, but may instead be used to couple hollow beams, tubes, or pipes formed by any method including cast, extruded, or machined hollow beams. Generally, the cross-sectional shape of the splice in its expanded form should conform to and tightly fit an inner cross-sectional shape of the hollow beams, pipes, or tubes to be coupled. Similarly, the cross-sectional shape of a beam bracket should conform to and tightly fit an outer cross-sectional shape of the hollow beam that it is supporting.

This disclosure is illustrative and not limiting. Further modifications will be apparent to one skilled in the art in light of this disclosure and are intended to fall within the scope of the appended claims. 

What is claimed is:
 1. A solar panel rack comprising: one or more sheet metal brackets, each sheet metal bracket comprising one or more upwardly pointing clinching tabs and one or more upwardly pointing protrusions; and an underlying support structure to which the sheet metal brackets are attached; wherein the clinching tabs are configured to be clinched to features on a solar panel or solar panel assembly to attach the solar panel or solar panel assembly to the solar panel rack in a desired location in a plane defined by the solar panel rack, and the protrusions are configured to facilitate electrical contact between the brackets and the solar panel or solar panel assembly when the features on the solar panel or solar panel assembly are clinched by the clinching tabs.
 2. The solar panel rack of claim 1, wherein the features on the solar panel or solar panel assembly are sandwiched between the protrusions and the clinching tabs when the clinching tabs are clinched.
 3. The solar panel rack of claim 1, wherein the upwardly pointing protrusions are configured to pierce an insulating coating on the features on the solar panel or solar panel assembly when the features are clinched by the clinching tabs.
 4. The solar panel rack of claim 1, wherein the upwardly pointing protrusions comprise sharp edges.
 5. The solar panel rack of claim 1, wherein the upwardly pointing protrusions comprise sharp points.
 6. The solar panel rack of claim 1, wherein the upwardly pointing protrusions have a conical volcano shape.
 7. The solar panel rack of claim 1, wherein each sheet metal bracket comprises one or more upwardly pointing positioning tabs configured to contact features on the solar panel or solar panel assembly to position the solar panel or solar panel assembly in the desired location.
 8. The solar panel rack of claim 7, wherein the positioning tabs of each sheet metal bracket are located in a square or rectangular arrangement in a central portion of a top panel of the sheet metal bracket and extend upward from the top panel.
 9. The solar panel rack of claim 1, wherein each sheet metal bracket is configured to position and attach adjacent corners of four solar panels or solar panel assemblies to the solar panel rack.
 10. The solar panel rack of claim 1, wherein each sheet metal bracket is formed by bending a sheet metal blank along bend lines predefined in the sheet metal blank by bend-inducing features.
 11. The solar panel rack of claim 1, wherein the electrical contact facilitated by the protrusions forms part of an electrical path from the solar panel or solar panel assemblies through the one or more sheet metal brackets and the underlying support structure to ground.
 12. The solar panel rack of claim 1, wherein: the underlying support structure comprises two or more hollow sheet metal beams arranged side by side and in parallel with each other to define a plane; and each sheet metal bracket has an inner cross-sectional shape substantially conforming to the outer cross-sectional shape of a corresponding hollow sheet metal beam to which it is attached.
 13. The solar panel rack of claim 1, wherein each sheet metal bracket comprises one or more tabs configured to engage corresponding slots or other openings in the underlying support structure to attach the sheet metal bracket to the underlying support structure, and one or more downwardly pointing protrusions configured to flex a portion of the underlying support structure to provide an elastic restoring force securing the tabs in the slots or other openings.
 14. The solar panel rack of claim 13, wherein: the underlying support structure comprises two or more hollow sheet metal beams arranged side by side and in parallel with each other to define a plane; each sheet metal bracket is attached to a corresponding one of the hollow sheet metal beams; and the one or more downwardly pointing protrusions on each sheet metal bracket are configured to flex an upper panel of the hollow sheet metal beam to which the bracket is attached to provide the restoring force securing the tabs in the slots or other openings.
 15. A solar panel rack comprising: one or more sheet metal brackets; and an underlying support structure to which the brackets are attached; wherein each sheet metal bracket comprises one or more upwardly pointing clinching tabs configured to be clinched to features on a solar panel or solar panel assembly to attach the solar panel or solar panel assembly to the solar panel rack in a desired location in a plane defined by the solar panel rack, one or more tabs configured to engage corresponding slots or other openings in the underlying support structure to attach the bracket to the underlying support structure, and one or more downwardly pointing protrusions configured to flex a portion of the underlying support structure to provide an elastic restoring force securing the tabs in the slots or other openings.
 16. The solar panel rack of claim 15, wherein: the underlying support structure comprises two or more hollow sheet metal beams arranged side by side and in parallel with each other to define a plane; each sheet metal bracket is attached to a corresponding one of the hollow sheet metal beams; and the one or more downwardly pointing protrusions on each sheet metal bracket are configured to flex an upper panel of the hollow sheet metal beam to which the bracket is attached to provide the restoring force securing the tabs in the slots or other openings.
 17. The solar panel rack of claim 15, wherein each sheet metal bracket comprises one or more upwardly pointing positioning tabs configured to contact features on the solar panel or solar panel assembly to position the solar panel or solar panel assembly in the desired location.
 18. The solar panel rack of claim 17, wherein the positioning tabs of each sheet metal bracket are located in a square or rectangular arrangement in a central portion of a top panel of the sheet metal bracket and extend upward from the top panel.
 19. The solar panel rack of claim 15, wherein each sheet metal bracket is configured to position and attach adjacent corners of four solar panels or solar panel assemblies to the solar panel rack.
 20. The solar panel rack of claim 15, wherein: the underlying support structure comprises two or more hollow sheet metal beams arranged side by side and in parallel with each other to define a plane; and each sheet metal bracket has an inner cross-sectional shape substantially conforming to the outer cross-sectional shape of a corresponding hollow sheet metal beam to which it is attached.
 21. The solar panel rack of claim 15, wherein each sheet metal bracket is formed by bending a sheet metal blank along bend lines predefined in the sheet metal blank by bend-inducing features. 